approved by the vice-chancellor dated 27.06. sc. geophysics...adikavi nannaya university m. sc....
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ADIKAVI NANNAYA UNIVERSITY
M. Sc. Geophysics Course Structure (W.E.F. 2019-20)
Paper
Code Title of the Paper
Internal
marks
External
marks
Total
marks
No. of
hours/week
No. of
Credits
Semester – I 100 550 650 36 26
GP101 Numerical methods and computer programming 25 75 100 4 4
GP102 Basics of Geology 25 75 100 4 4
GP103 Physics and dynamics of the Earth 25 75 100 4 4
GP104 Signal processing 25 75 100 4 4
GP105 Computer programming lab - 50 50 3 2
GP106 Basics of Geology lab - 50 50 3 2
GP107 Physics and dynamics of the Earth lab - 50 50 3 2
GP108 Signal processing lab - 50 50 3 2
GP109 Viva-Voce - 50 50 - 2
Semester – II 100 550 650 36 26
GP201 Essentials of Geology 25 75 100 4 4
GP202 Principles of Remote Sensing techniques 25 75 100 4 4
GP203 Seismology 25 75 100 4 4
GP204 Gravity and Magnetic methods of Exploration 25 75 100 4 4
GP205 Essentials of Geology lab - 50 100 3 2
GP206 Principles of Remote Sensing lab - 50 50 3 2
GP207 Seismology lab - 50 50 3 2
GP208 Gravity and Magnetic methods of Exploration lab - 50 50 6 2
GP209 Viva-Voce - 50 50 - 2
Semester – III 100 600 700 36 28
GP301 Electrical methods of Exploration 25 75 100 4 4
GP302 Seismic methods of Exploration 25 75 100 4 4
GP303 Marine Geophysics 25 75 100 4 4
GP304 Seismic data processing and interpretation 25 75 100 4 4
GP305 Electrical methods of Exploration lab - 50 50 3 2
GP306 Seismic methods of Exploration lab - 50 50 3 2
GP307 Marine Geophysics lab - 50 50 3 2
GP308 Seismic data processing and interpretation lab - 50 50 3 2
GP309 Seminar presentation - 50 50 3 2
GP310 Viva-Voce - 50 50 - 2
Semester – IV 125 575 700 36 30
GP401 Electromagnetic methods of exploration 25 75 100 4 4
GP402 Well logging and formation evaluation 25 75 100 4 4
GP403
Elective paper (Any one of the following two papers)
(i) Petroleum Geology and Geophysics 25 75 100
4 4
(ii) Environmental & Groundwater Geophysics 4
GP404 Electromagnetic methods of exploration lab - 50 50 3 2
GP405 Well logging and formation evaluation lab - 50 50 3 2
GP406 Elective paper lab - 50 50 3 2
GP407 Project work (Report, presentation and Viva) 50 150 200 - 10
GP408 Viva-Voce - 50 50 - 2
425 2275 2700 110
Note:
1. Project work is to be carried out during the summer vacation after the first year and/or during
December to January season in the second year for 45-60 days.
2. One hour each in every semester is to be allocated for sports and library wherever it is possible
Approved by the Vice-Chancellor dated 27.06.2019
ADIKAVI NANNAYA UNIVERSITY
M. Sc. Geophysics Course – I semester syllabus (wef 2019-20)
101: Numerical Methods and Computer programming
Unit I: Numerical solution of algebraic and transcendental equations - methods of bisection, false position
and Newton - Raphson; Interpolation - finite differences, symbolic relations, Newton’s formula, Gauss' central difference formulae, Bessel’s formula, Lagrange's formula, Richardson's extrapolation; Numerical
differentiation - maximum and minimum of a tabulated function, cubic spline method; Numerical Integration
- Trapezoidal rule, Simpson' s formulae, Romberg’s integration, Weddle's formula, numerical double
integration; Numerical solution of ordinary differential equations, solution by Taylor’s series, Picard's method of
successive approximations, methods of Euler and Runga-Kutta; Finite element methods, basic concepts, boundary and
initial value problems, variational formulation, variational methods of approximation, Ritz method, finite element
analysis of 1d and 2d problems.
Unit II: Solution of linear system of equations – Matrix inversion method, Gauss’ elimination method, Gauss-Jordan method, Jacobi’s method, Gauss Seidel method, method of factorization, Centro-symmetric equations,
ill-conditioned systems, generalized inversion techniques, properties, linear inversion, non-linear inversion –
incorporating prior information, parametric inversion, assessing the uncertainty in inverted models.; Principles of least squares – fitting of polynomials, normal equations, linear and non-linear curve fitting, sum of
exponentials, Chebysev polynomials.
UNIT III: C-Programming: character set, delimiters, keywords, identifiers, constants, variables, rules for defining variables, data types, comma and conditional operators, arithmetic operators, relational operators,
logical operators, bitwise operators, priority of operators, input and output in C, formatted and unformatted
functions, library functions.
IF statement, IF…. ELSE statement, nested IF, GOTO statement, break statement, CONTINUE statement,
SWITCH-CASE statement, nested switch statement, FOR statement, WHILE statement, DO-WHILE
statement, arrays, working with string and standard functions.
UNIT IV: Pointers, pointer declaration, arithmetic operations with pointers, pointers and arrays, array of
pointers, pointers to pointers, pointers and strings, void pointers, function definition and declaration, prototypes, types of functions, call by value and reference, functions returning more values, functions with
arrays and pointers, recursion, pointer to function, storage classes.
Preprocessor directives, structures and unions, bit wise operators, files, command line arguments, dynamic
memory allocation, graphics in C.
Text Books
1. S. S. Sastry, Introductory methods of Numerical analysis, 2005, Prentice-Hall of India, New Delhi.
2. S. S. Rao, Optimization theory and applications, 1991, Wiley Eastern Limited, New Delhi. 3. Yashvant P Kanetkar, Let us C, BPB Publications
Reference books
4. V. Rajaraman, Computer oriented numerical methods, Prentice-Hall of India Pvt. Ltd., New Delhi.
5. V. Rajaraman, Computer basics and C Programming, Prentice-Hall of India Pvr. Ltd., New Delhi.
102: Basics of Geology
UNIT I: Introduction and Scope of Geology: Branches of Geology, relation with other sciences and
Geophysics. Weathering and Erosion – physical, chemical and biological weathering, Geological work of
wind - erosion – its products, sediment transport by wind, types of dunes. Geological work of glaciers, featured formed by glacial transportation and related features. Geological work of rivers – initial, youth,
mature and old stages of river, important features formed by river action – canyons, meanders, Ox - bow
lakes, flood plains, natural levees, denudation, Peni plains, monad rocks, Drainage patterns, types of deltas
and process of their formation.
UNIT II: Geomorphology: Fundamental concepts of Geomorphology, principles of Geomorphology,
Geomorphological features formed by geological work of mountains and mountain building activity, plate tectonics and earth quakes, seas, waves and currents of sea and their transportation. Features formed by
marine erosion, deposition; Evolution of major geomorphic process in India; Study of topographic and
thematic maps.
UNIT III: Physiographic divisions of ocean floor: Continental margins, abyssal plains, seamounts and guyots,
aprons, submarine canyons, deep sea channels, turbidity currents and submarine sedimentation, mid oceanic
ridge system and its structure, aseismic ridge systems, island arcs, trenches, hotspots and their mechanism, Coral reefs and processes of formation of coral reefs; Temperature, salinity and density of sea water,
composition of sea water.
UNIT IV: Introduction to Stratigraphy: Principles of Stratigraphy and its classification, Principles of
Correlation, fossils and their importance in Stratigraphy, physiographic divisions of india, Stratigraphic units
of india, Geological Time Scale; Indian stratigraphy (Introduction, classification and economic importance of
Archeans, Dharwars, Cuddapah, Vindhyan, Gondwana groups, Deccan traps, Siwaliks and Quaternary formations etc.)
Text Books/
1. Introduction to Physical Geology by A. K. Datta,
2. A text book of Geology by P. K. Mukherjee, World Press. 3. Principles of Geomorphology by W. S. Thornbury, Wiley Eastern, New Delhi.
4. Indian geology and stratigraphy by M. S. Krishnan,
Reference books:
1. Principles of Physical Geology by A. Holmes and D. L. Holmes.
2. Historical Geology by Ravindra Kumar, 3. Geology of India by M. Ramakrishnan and R. Vaidyanadhan,
103: Physics and Dynamics of the Earth
Unit I: The Universe and the solar system: Modern theories about the origin of the solar system, the earth, meteorites and other planetary bodies; Age of the Earth and the Universe.
Interior of the Earth: Major subdivisions of the Earth – Crust (continental and oceanic), Mantle (upper and lower) and Core (outer and inner) their structures and composition, variation of density, temperature, pressure,
acceleration due to gravity and elastic constants within the Earth.
Thermal history of the Earth – Terrestrial heat flow measurements in land and oceanic areas, methods, thermal properties of rocks, transfer of heat within the Earth, the Earth’s internal sources of heat, continental heat
flow - variation of continental and oceanic heat flows.
Unit II: Gravity field and figure of the earth - Earth’s gravitational attraction, force of gravity on the surface
of the Earth, figure of the Earth, Clairaut’s theorem, international gravity formula, rotation of the earth,
gravitational potential, spheroid and geoid; Isostasy and theories of isostasy.
Theory of continental drift, sea-floor spreading hypothesis - Vine-Matthews-Morley hypothesis, rates of sea
floor spreading, drift of the Indian continent; Plate tectonics - The lithosphere, lithospheric plates, distribution
of major and lithospheric plates, types of plate margins, triple junctions, their evolution and stability; Forces acting on lithospheric plate, Euler poles of rotation, absolute plate motions, plate tectonics and evolution of
Himalayas, Mantle viscosity, concepts of mantle convection models, coupling between plates and mantle
convection;
UNIT III: Geochronology – Dating of rocks, closed and open systems, Uranium-Lead method: the
Concordia-Discordia diagram, Interpretation of discordant ages, isochron diagrams, Potassium-Argon
method, Rubidium-Strontium method, Argon-Argon method, Radioactive Carbon and Tritium methods, mass spectrometer, Fission-track dating, age of the Earth; History of Precambrian chronology, subdivisions of
Precambrian time.
UNIT IV: Geomagnetism – General features of Earth’s magnetic field, field of uniformly magnetized sphere;
The magnetic fields of external and internal origins and their separation, the origin of the Earth’s internal
magnetic field, the dynamo theory and dynamo models; IGRF, secular variations and westward drift of the Earth’s magnetic field; Paleomagnetism, Field reversals, polar wandering.
Transient magnetic variations, Quiet day solar daily variation Sq, magnetic storms, auroras and airglow,
theories of magnetic storms and aroras, the physical properties of upper atmosphere, the magnetosphere; Natural Remanent Magnetisation (NRM) - Measurement of NRM by Astatic and Spinner magnetometer,
demagnetization effect.
Text Books
1. The Solid Earth, An introduction to global geophysics, C.M. R. Fowler, Cambridge University Press, Second edition.
2. Fundamentals of Geophysics by William Lowrie, Cambridge University Press.
Reference books
1. Plate tectonics and crustal evolution by Kent C. Condie, Butterworth-Heinemann
2. Interior of the Earth by M. H. P. Bott. Edward Arnold
3. Geodynamics of the Indian Peninsula and the Indian plate margins by R. K. Varma, Oxford & IBH publishing
co. pvt. Ltd.
104: Signal Processing
UNIT I: Definitions of signal and noise, various classes of signals – continuous, piece wise continuous, absolute integrable, singularity, unit impulse, unit step etc., Fourier series, Dirichlet conditions, Fourier
analysis of continuous, discontinuous, even and function, Gibb’s phenomenon, complex form of Fourier
series; Fourier integral theorem, Fourier sine and cosine integrals.
UNIT II: Fourier Transforms: The Fourier Transform (FT) and its properties – linear, scaling, shifting
properties, modulation, frequency and shifting theorems, derivation and integration theorems; Fourier transforms of gate, exponential, impulse, step, singularity and periodic functions; Amplitude, phase and power
spectra; Spectrum of observational data, Discrete Fourier Transform (DFT) and Fast Fourier Transform (FFT),
FFT algorithm.
UNIT III: Z-Transforms: The Z-Transform (ZT) and its properties, ZT of casual and non-casual sequences,
use of ZT in Geophysics; Inverse ZT, analysis of discrete-time systems, application of ZT to the analysis of
Discrete-Time systems; Introduction to Hankel, Hilbert, Wavelet, and Walsh transforms and their applications in geophysics.
Time-series analysis: Discrete time signals, auto and cross correlations and their applications; convolution,
methods and properties of convolution; Deconvolution and its applications in signal analysis, impulse response and transfer functions, delay properties of wavelets,
UNIT IV: Band limited signals, sampling theorem, Nyquist frequency, aliasing, sampling of band and time limited signals, reproduction of continuous function from sampled data; windowing, types of windows,
spectral leakage; Wiener Khinchin theorem, spectrum computation via autocorrelation and periodogram.
Digital filtering, design, amplitude and phase response, low-pass, high-pass and band-pass filters, optimum
filters, Butterworth filter, recursive and non-recursive filters, optimal and optimum Weiner filters;
deconvolution, deterministic and statistical deconvolution, predictive deconvolution, time-variant deconvolution, frequency filtering.
Text Books
1. Seismic data Analysis by Oz Yilmaz, Vol (I), Society of Exploration Geophysicists, Tulsa, USA.
2. Digital signal processing and time series analysis by Enders A. Robinson and M. T. Silvia, Holden-Day, The University of California.
3. Digital signal processing by S. Salivahanan, Tata McGraw Hill Education (India), Pvt. Ltd.
Reference books:
1. Spectral analysis in Geophysics by B. Markus Bath, Elsevier Science.
ADIKAVI NANNAYA UNIVERSITY
M. Sc. Geophysics Course – II Semester Syllabus (w.e.f. 2019-20)
201: Essentials of Geology
UNIT I: Crystallography: Introduction, Elements of crystallography – Characters of crystals, symmetry elements, Brief classification of 6 systems; Basics of physical properties of minerals, Isomorphism,
polymorphism; Classification of minerals, brief description of physical properties of quartz, feldspar, mica,
pyroxene, amphibole and garmet group and clay minerals.
UNIT II: Petrology: Definition, classification of rocks of rocks - Igneous, sedimentary and metamorphic rocks, distinguishing features between three types of rocks; Composition and constitution magma, forms of
Igneous rocks, structure of igneous rocks, brief classification of igneous rocks, origin of sedimentary rocks,
classification of sedimentary rocks based on their structures and textures, metamorphism, types, grades and zones of metamorphism, brief classification of metamorphic rocks.
UNIT III: Economic Geology: Origin and classification of economic minerals, geological thermometers,
magmatic concentration, hydrothermal process, sedimentation, metamorphism, metallic and non – metallic
minerals, placer deposits; Introduction to Hydrocarbons (including Petroleum, natural gas, coal, gas hydrates, coal bed methane, shale gas, poly metallic and manganese nodules).
UNIT IV: Structural Geology: Principles of stress and strain, structural features of rocks – primary and
secondary structures, strike and dip. Folds – introduction, classification and origin. Faults – Introduction, classification, causes of faults and recognition of faults in the field. Joints – introduction, Classification and
origin unconformities – definition, types and origin of unconformities, Different types of field and laboratory
scales used in the preparation of geological maps, different symbols used in the preparation of geological
maps.
Text Books
1. Rutley’s elements of mineralogy by C.D. Gribble, 2. An introduction to rock forming minerals by W. A. Deer, R. A. Howai and J. Zusmann, Longman
group Ltd., London.
3. A text book of Geology by P. K. Mukherjee, World Press.
Reference books
1. Structural geology and tectonic principles by P. C. Badgley. 2. Igneous and Metamorphic Petrology by A. Philpots, 1992.
3. Structural Geology by M. P. Billings, Printice Hall of India Pvt. Ltd., New Delhi.
4. Principles of petrology by G.W. Tyrrel, B. I. Publications Pvt. Ltd.
202: Principles of Remote sensing techniques
UNIT I: Electromagnetic radiation, electromagnetic spectrum, Planck’s law, Wien’s displacement law,
Interaction with the atmosphere, earth’s surface and matter, selective and non-selective scattering, impact of scattering on remotely sensed data, atmospheric windows and absorption bands.
Spectral reflectance curves of water, snow, clouds, vegetation, soils, rocks/minerals; imaging and non-imaging sensors, radiometers, spectrometers, spectro radiometers, line scan systems, array scanning systems,
multispectral scanner systems, whiskbroom and pushbroom imaging systems, circular/conical/side scanning
systems; sensor characteristics, spatial resolution, spectral resolution, radiometric resolution and temporal
resolution.
UNIT II: Platforms for data acquisition – Air borne and space borne platforms; Satellite orbits - geo-
synchronous and sun-synchronous orbits; Indian Remote Sensing Satellites.
Microwave remote sensing: Wavelength bands, geometry of the radar image, passive microwave radiometers,
penetration of the radar signal, polarization; advantages and disadvantages of passive microwave remote sensing; active microwave remote sensing: SLAR, SAR; look direction and look angle, Interpreting
Brightness values, satellite image radars, LiDAR, scope of micro wave remote sensing in earth science
applications.
UNIT III: Thermal remote sensing: thermal radiometry, microwave radiometers, thermal scanners, thermal
properties of objects, geometry of thermal images, thermal image and its interpretation, heat capacity mapping mission, TM thermal data, scope of thermal remote sensing in earth science applications.
Hyperspectral remote sensing: spectroscopy, image cube, AVIRIS, spectral matching, spectral mixing
analysis, data libraries, MODIS, processing of hyper-spectral data, applications of hyperspectral remote sensing, scope of hyperspectral remote sensing in various earth science applications.
UNIT IV: Image resolution, field data and image interpretation, target variables, system variables, operation conditions, measurement of resolution, mixed pixels, kinds of field data, nominal data, field radiometry,
locational information, geographic sampling, image interpretation tasks, strategies, keys and equipment.
Elements of image interpretation, collateral information, interpretive overlays, preparation for manual
interpretation, image scale calculations, image registration, image enhancement, image filtering, image
smoothening, image classification – Supervised, Unsupervised and Fuzzy classifications, classification accuracy assessment.
Text Books/Reference books
1. Remote sensing of the environment: An earth resource perspective by John R. Jensen, Second edition, Pearson Education, Inc.
2. Digital remote sensing by Prithvish Nag and M. Kudrat, Concept publishing company, New Delhi.
3. Hyperspectral data, analysis techniques and applications, Ed. R. R. Navalgund and S. S. Ray, Indian Society of remote sensing.
Reference books
1. Remote sensing geology by Ravi. P. Guptta, Springer International Edition, Springer (India) Pvt. Ltd.
New Delhi.
2. Remote sensing and image interpretation by T. M. Lillesand, Kiefer, R. W., and Chipman J.W., Wiley.
203: Seismology
UNIT I: Introduction: Elastic theory – elastic, inelastic and plastic behavior of material, the stress matrix, the
strain matrix, longitudinal strain, dilatation and shear strain, Elastic constants and internal relationships
between them, elastic parameters in terms of lame constant; Seismic waves – Body waves - Longitudinal waves, Transverse waves - Surface waves - Rayleigh waves, Love waves; Seismic wave equation and the
solution to the seismic wave equation; The energy in seismic disturbance, the attenuation of seismic waves,
the dispersion of seismic waves.
UNIT II: The earthquake seismology: Introduction, definition of an earthquake, focus, epicenter, location of
the epicenter of an earthquake, classification of earthquakes – based on the depth of the focus and on the
causative mechanism; Travel-time curves and velocity depth curves; Earth quake size – Intensity, magnitude and the relation between them, earthquake frequency, energy released in an earthquake; Secondary effects of
an earthquake.
Continental margins: Types of continental margins – Passive, Active and transform continental margins, classification and distribution of continental margins on the globe, the global seismicity, belts of active
seismicity; hotspots and mantle plumes, plume generation mechanism, evidence of mantle plumes from
seismology and geoid.
UNIT III: Seismometers - Principle of seismometer – vertical motion seismometer, horizontal motion
seismometer, the equation of seismometer – effect of instrumental damping, long period seismometer, short period seismometer, broad band seismometer; The seismogram – Analogue recording, digital recording,
phases on a seismogram.
UNIT IV: Analysis of earthquakes: Source parameters of an earthquake and their determination; Analysis of earthquake focal mechanisms – single couple and double couple radiation pattern, fault plane solutions,
machanics of faulting, focal mechanism at active plate margins, focal mechanism at continental collision
zones; Earthquake prediction – prediction of the location, time and size of an earthquake, reservoir induced seismicity, seismic zonation.
Text Books
1. Fundamentals of Geophysics by William Lowrie, Cambridge University Press.
2. Introduction to Seismology by Markus Bath,
Reference books
1. Principles of Seismology by Agustín Udías and Elisa Buforn, Cambridge University Press, 2nd Edition.
2. An Introduction to Seismology by Jonathan Frost, Larsen and Keller Eduction.
204 - Gravity and Magnetic methods of exploration
UNIT I: Principle of gravity and magnetic prospecting: Properties of Newtonian potential, Laplace’s and
Poissons’s equations, Green’s theorem, Gauss’ law, continuation integral, concept of gravity anomaly; Rock
densities, factors controlling rock densities; Principles of gravity prospecting instruments - static and astatic gravimeters, Zero-length spring; Concept of magnetic anomalies, Origin of magnetic anomalies, induced and
remanent magnetizations; Dependence of magnetic anomalies on latitude and orientation; Magnetic
susceptibility, factors controlling susceptibility, magnetic classification of minerals and rocks, laboratory and in-situ methods of determining susceptibility; Principles of magnetic prospecting instruments - Fluxgate,
Nuclear, Proton precession and Optical pumping magnetometers.
UNIT-II: Gravity and magnetic surveying: Establishment of base stations, gravity drift correction; Reduction of gravity and magnetic data; Free-air, Bouguer and Complete Bouguer gravity anomalies and magnetic
anomalies; Bouguer density and its in-situ determination – Nettleton’s density profiling and Seigert’s
methods; Airborne magnetometry, orientation mechanisms, survey techniques, data acquisition and reduction; Gradient measurements; Satellite magnetometry.
Regional, residual and noise anomalies in gravity and magnetics; Regional residual separation - graphical,
average, grid and curve fitting techniques, reliability of different types of residuals; Vertical derivative calculations; Equivalent stratum, upward and downward continuations - classical methods using continuation
integral, harmonic analysis and Fourier transformation.
UNIT III: Interpretation of gravity and magnetic anomalies: Qualitative interpretation - Nature of anomalies,
identification of structural features and litho contacts from contour maps; Ambiguity in gravity and magnetic
interpretation, strategies for resolving the ambiguity.
Quantitative interpretation: Concepts of forward modeling and inversion; Forward modeling of gravity
anomalies - Gravity anomaly equations and characteristics of anomaly profiles of point and line masses,
circular discs, vertical cylinders, sheets, faults and rectangular slabs; Generalized equations for the magnetic anomalies of single pole, sphere, line dipoles, dykes, sheets and faults, anomaly equations and characteristics
of anomaly profiles; Interpretation by thumb rules and characteristic curves; Poisson’s relation, similarity of
magnetic anomalies of two-dimensional bodies in different components; Magnetic equivalence of dykes, faults and anticlines.
UNIT IV: Forward modeling of gravity and magnetic anomalies of two-dimensional and three-dimensional bodies - graticules, computer models; Inversion of gravity anomalies of 2-D polygonal bodies; Automatic
gravity modeling of sedimentary basins by Bott’s method and density interfaces, concepts of density contrast
and density difference, inversion of gravity anomalies of density interfaces; Mass estimations from gravity
anomalies; Magnetic inversion - 2d polygonal bodies, dykes and magnetic interfaces; Interpretation in frequency domain, depth calculations.
Application of gravity and magnetic methods for regional geological mapping, oil and mineral exploration with special reference to salt domes, structural traps, sulphide ores, ferrous and non-ferrous ores, diamonds,
placer deposits, coal, groundwater, engineering problems.
Text Books
1. Milton B.Dobrin and Carl H.Savit, Introduction to Geophysical Prospecting, 1988, McGraw-Hill
International Edition, Geology Series, New Delhi
2. Telford W. M. et. al., Applied Geophysics, 1988, Oxford & IBH Publishing Co. Pvt . Ltd., New Delhi.
3. Gravity and magnetic methods of prospecting by B. S. R. Rao and I. V. R. Murthy.
Reference books
1. I. V. Radhakrishna Murthy, Gravity and magnetic Interpretation in Exploration Geophysics,
Geological Society of India Memoir No.41.
ADIKAVI NANNAYA UNIVERSITY
M. Sc. Geophysics Course Structure (w.e.f. 2019-20)
301: Electrical methods of exploration
UNIT – I: Classification of electrical methods, Electrical properties of rocks and minerals – electrical
potentials, electrical conductivities, polarization potentials; Laboratory measurements of resistivities,
dielectric constants, Factors affecting the resistivity of rocks; Archie’s law, isotropy and anisotropy, Dar zarrowk parameters – longitudinal conductance and transverse resistance, Ohm’s law; Concepts of true
resistivity, apparent resistivity and strip resistivity, apparent resistivity for multi layered earth, principle of
reciprocity, reflection coefficient, principle of equivalence and suppression.
UNIT – II: Resistivity methods: Potentials in homogeneous media - single current electrode at depth, single current electrode at surface, two current electrodes at surface, current distribution; effect of inhomogeneous
ground - Distortion of current flow and potential at plane interface, surface potential at horizontal beds;
Potential due to buried sphere, effect of anisotropic ground and topography; Equipment for electrical resistivity field work – power sources, meters, electrodes and wires, different electrode layouts and field
procedures.
UNIT – III: Interpretation of resistivity data: Resistivity modeling, resistivity transforms and their use;
Vertical sounding – two and multiple horizontal beds - types of sounding curves - interpretation of sounding
curves – curve matching, partial curve matching - multi layer approach; interpretation using auxiliary curves;
Lateral resistivity mapping – vertical contacts and vertical dykes, mapping three-dimensional anomalies, measurement of overburden depth and resistivity; Introduction to computer inversion of sounding curves -
Basic approach and iterative inversion.
UNIT – IV: SP Method: Origin – different theories, equipment and field techniques; SP anomalies over
sphere & sheet etc., interpretation of SP anomalies.
Induced polarization method: Electrode polarization, membrane polarization. Methods of IP measurement - Frequency & Time domain methods, parameters measured, relation between time and frequency domain
measurements, field equipment and field procedures, noise sources, IP sounding and profiling, plotting of
results, pseudo sections, interpretation, spectral IP, magnetic induced polarization.
Application of SP, resistivity & IP methods in regional geology, mineral and ground water explorations.
Text Books 1. Applied Geophysics (2
nd edition) by W.M Telford, L. P. Geldart and R. E. Sheriff, Cambridge
University Press.
2. Electrical methods in Geophysical Prospecting by George Vernon Keller and Frank C. Frischknecht,
Pergamon Press. 3. D.C. Geo electric sounding by P.K Bhattacharya & H.P. Patra
Reference books
1. Geo sounding principles Vol. 1 by O.Koefoed.
302: Seismic methods (land) of exploration
UNIT – I: Fundamentals of seismic methods of exploration: Propagation characteristics of seismic waves in media - Elastic wave velocities of rocks - factors affecting elastic wave velocities; Seismic anisotropy,
acoustic impedance, ray paths in layered media, reflection and refraction of seismic waves at interfaces,
Snell’s law, critical refraction, diffraction, dispersion, multiples, ghost reflections and reverberations, phases, Zeoppritz equations; Seismic reflection and refraction methods of exploration – fundamental differences.
UNIT II: Seismic Energy Sources: Explosive and non-explosive sources - dynamite, Vibroseis – sweep correlation, sweep control, sweep design, side-lobe noise, Vibrator problems and possible solutions,
determination of field parameters for optimized vibrosies operation; Thumper, Land air-gun and other land
energy sources; Penetration signatures of various energy sources; Seismic Detectors/Receivers: Geophone
and types of geophones – Frequency response and damping, electrical characteristics, physical characteristics, response testing, cables; Detector arrays, array design and array response; Seismic instrumentation: Basic
components, instrument noise and sampling, amplification, A/D conversion and conversion operations,
filtering, dynamic range, recording formats and recording channels, telemetry systems, sign-bit recording.
UNIT III: Seismic reflection surveys: Geometry of reflected ray paths, travel time curves and calculation
of layer parameters, single and multiple horizontal and dipping reflectors; Ray paths for multiple reflections,
the seismic trace, shot gather, CMP gather; Multichannel reflection surveying - multichannel reflection survey design, vertical and horizontal resolutions, split spread and end-on shooting, common depth point and
common mid pint surveying; Multi component seismic reflection surveys, Vertical seismic profiling; display
of reflection data – reflection seismogram; Seismic survey parameters – survey planning and parameter optimization.
Seismic 3D surveys: Introduction to 3D layouts - swath, brick, odds and evens, zig-zag, button patch, full range 3D and loop survey.
UNIT IV: Seismic refraction surveys: Geometry of refracted ray paths - single and multiple horizontal and
dipping planar interfaces, faulted planar interfaces - calculation of layer parameters; Geometry of refracted ray paths non planar interfaces – generalized reciprocal method of interpretation; The hidden and blind layer
problems - reversed and un reversed refraction profiling - refraction travel time curves - refraction across
faulted interface; Refraction survey procedures, fan shooting, broad-side shooting, long refraction profiles.
Text Books
1. Milton B. Dobrin and Carl H. Savit, Introduction to Geophysical Prospecting, 1988, McGraw-Hill
International Edition, Geology Series, New Delhi
2. Telford W. M. et. al., Applied Geophysics, 1988, Oxford & IBH Publishing Co. Pvt . Ltd., New Delhi.
3. Philip Kearey and Michael Brooks, An introduction to geophysical exploration, 2000, Blackwell
Science.
Reference books
1. Seismic hydrocarbon exploration 2D and 3D techniques by Hamid N Alsadi, Springer.
303: Marine Geophysics
UNIT I: Marine gravity and magnetics: Gravity and magnetic survey procedures in marine environments,
gravity and magnetic instrumentation for sea surface and under water measurements, reduction of marine
gravity and magnetic data and calculation of anomalies; Continental and oceanic gravity anomalies, gravity
anomalies across mountain chains, oceanic ridges and subduction zones and continental margins, Isostatic gravity anomalies.
UNIT II: Oceanic magnetic anomalies, sea floor spreading, linear magnetic anomalies, dating the ocean floor, geomagnetic time scale, geomagnetic polarity, geomagnetic polarity time scale, frequency of polarity
reversals, early Mesozoic and Paleozoic reversal history; Magnetostratigraphy.
UNIT III: Marine seismics: Marine seismic energy sources: Air-Guns – Air-Gun arrays, Sparker, Maxipulse, Water gun, Steam gun; Penetration signatures of various energy sources; Detectors/Receivers for marine
seismics: Hydrophones - Types of hydrophones, streamers, depth control devices, streamer design and
shooting techniques, streamer heading and noise; Detector arrays, array design and array response; Marine 2D reflection and refraction shooting and 3D, 3D ocean bottom survey, marine sonobuoy surveys.
UNIT IV: Navigation in marine surveys: Radio navigation, Navigation systems, navigation planning for an offshore program using radio positioning systems; Satellite navigation– Global Positioning System (GPS).
Seabed imaging: Single beam echo sounding, echo sounders and echo sounding profiles, imaging bathymetric
data, swath mapping – side scan sonar, multibeam swath sounding, hybrid systems, bathymetric measurements using electromagnetic waves.
Text Books:
1. Marine geophysics by E. J. W. Jones, John Wiley Publications.
2. Introduction to Geophysical Prospecting by Milton B. Dobrin and Carl H.Savit, 1988, McGraw-Hill
International Edition, Geology Series, New Delhi.
Reference books: 1. Fundamentals of Geophysics by William Lowrie, Cambridge University Press. 2. Applied Geophysics by Telford W. M. et. al., Oxford & IBH Publishing Co. Pvt . Ltd., New Delhi.
304: Seismic data processing and interpretation
UNIT I: General stages in seismic data processing or processing sequence; Preprocessing – Demultiplexing, editing, true amplitude recovery (TAR), static correction, deconvolution, CDP gather, preliminary stacking;
Processing analysis – Velocity analysis, static analysis, deconvolution analysis, filter analysis and ramp
analysis; Processing – Normal Move Out, residual static correction, pre-stack ramp, CDP stack, deconvolution, frequency filtering, final stacking, migration.
UNIT II: Pre-processing: Reflection data processing, static and dynamic corrections, study of shot gather, identification of seismic events and noise; analysis of analog records, seismic sections, automatic processing;
format conversion, trace editing, pre-filtering, gain applications, geometric spreading correction, programmed
gain control, RMS and instantaneous AGC and relative trace balancing; deconvolution, construction of
convolution model, effect of random noise, multiple attenuation, dip filtering, deconvolution strategies.
UNIT III: Processing Analysis: Velocity analysis – Types of velocities, Velocity determination from wells,
seismic reflection data; Velocity searching techniques – manual computations, computer assisted computations, criteria for velocity function estimation; Velocity accuracy – statistical errors, non statistical
errors, effect of RMS velocity error on interval velocity estimation; Vertical stack, diversity stack and CDP
stack; velocity analysis and static corrections; NMO, factors affecting velocity analysis, residual static
corrections, refraction static corrections; migration, different methods, dip move out correction (DMO), prestack migration, AVO analysis.
UNIT IV: Seismic sections - plotting, display, events, isochronal and isopach maps, identification of geological structures, structural and stratigraphic traps - pitfalls in interpretation. Hydrocarbon indicators,
bright spots, seismic attributes and interpretation.
Seismic stratigraphy: Introduction - stratigraphic patterns, depositional patters and lithology - seismic
sequence - seismic facies - simple and complex reflection configuration - seismic reflection character analysis.
Text Books
1. Seismic data Analysis by Oz Yilmaz, Vol. I, Society of Exploration Geophysicists, Tulsa, USA. 2. Introduction to Geophysical Prospecting by Milton B. Dobrin and Carl H. Savit, 1988, McGraw-Hill
International Edition, Geology Series, New Delhi.
3. Fundamentals of Geophysical Data Processing by J. Clearabot.
Reference books
1. Seismic data Analysis by Oz Yilmaz, Vol. II, Society of Exploration Geophysicists, Tulsa, USA.
ADIKAVI NANNAYA UNIVERSITY
M. Sc. Geophysics Course – IV semester syllabus (w.e.f. 2019-20)
401: Electro Magnetic methods of Exploration
UNIT I: Basics: Electromagnetic induction, primary and secondary fields and their relations – real and
imaginary components, inductive and resistive limits, response function, elliptical polarization, Maxwell’s
equations, boundary conditions, wave equation, plane wave characteristics, propagation of EM wave in conducting media, wave number, impedance, skin depth versus effective depth, Brief classification in EM
methods; Brief principles of solving electro dynamic problems including scale modelling.
UNIT – II: Field of magnetic dipole and electric dipole (both transient and frequency domains) in air and
homogeneous isotropic space. Response of stratified medium to the above sources. Frequency and transient
response of local conductors, sphere and cylinder, in homogeneous field. Effect of frequency and magnetic permeability on the secondary fields. Sphere as an example, generalized induction parameter. Effect of
overburden and host rock on EM response.
Methods using artificial fields: Surface low frequency methods, Turam, Tilt angle and slingram methods -principles, field procedures and various corrections, quantitative interpretation. Operation at low induction
numbers. Surface transient methods, description of different current functions, various T-R configurations
general field procedures, interpretation of surface transient method data.
UNIT – III: Radio wave methods: VLF EM/EMR, Interpretation of VLF EMR data, Ground penetrating
Radar (GPR), applications in shallow depth investigations; EM sounding - field procedures, geometric versus
parametric sounding, interpretation.
Methods using natural fields: Principle of MT, origin of earth’s natural EM field, magneto telluric source
field characteristics. MT field procedures and instrumentation, Cagniard’s relation, impedance over N- layer medium apparent resistivity and phase MT tensor; Swifts optimum rotation, remote reference
magnetotellurics; 1-D, 2-D interpretation of magnetotelluric data; CSAMT, AMT & AFMAG (Brief
principles only).
UNIT – IV: Telluric current method: principle and field procedure; Telluric profiling, interpretation of
telluric data.
Airborne EM methods: Different systems in operation - continuous wave, transient (INPUT) and rigid
broom helicopter system, passive airborne EM systems - AFMAG & VLF, different noises in AEM systems
and methods of suppression, interpretation of AEM data.
Geomagnetic depth sounding: Origin and classification of long period geomagnetic variations, separation of
magnetic field of internal and external origin, normal and anomalous fields; Magnetometer array studies, Interpretation of geomagnetic depth sounding data.
Text Books
1. Applied geophysics by Telford et.al revised edition, Cambridge University Press.
2. Electrical methods of geophysical prospecting by Keller & frischknechtt
3. Geosounding principles Vol.II by Patra & Mallick, Elsevier Scientific Publicatin Company Ltd.
Reference books
1. Electromagnetic methods, vol I and II, Nabighian, SEG publications.
402: Well logging and formation evaluation
UNIT-1: Petrophysical parameters – porosity - water saturation – permeability - formation factor - formation temperatures - resistivity index - formation factor porosity relationships; Borehole environment – distribution
of resistivities around the borehole; Data acquisition - surface equipment – down hole equipment – tools –
sensors – detector – signals; Open hole and cased hole operations - logging while drilling (LWD).
UNIT-2: Electrical logging: SP log, resistivity logging, conventional systems, focused systems, normal,
lateral, laterolog, micrologging devices, induction log; Porosity logs: Acoustic logging, bore hole
compensation, Neutron & Density loggings; Radioactive logging –Gamma ray and Natural Gamma Ray Spectroscopy logs (NGS); Miscellaneous logs: Dipmeter, Carbon-Oxygen logging, pulsed neutron log,
cement bond and variable density log, NMR log.
UNIT-3: Determination of porosity from resistivity and non-resistivity porosity tools, density, neutron-sonic
logs, lithology and porosity from cross-plots, determination of fluid saturation from resistivity porosity cross
plots, permeability from logs, Quick look interpretation, identification of clean, shaly and hydrocarbon bearing zones, minerals. Computer processed interpretation (CPI) software. Complex reservoir and fractured
reservoir interpretation, formation fluid sampling, MDT, RFT, sidewall casing.
UNIT-4: Production logging: fundamentals of production logging – applications – temperature, pressure,
flow meter and radioactive tracer tools, applications; Composite log, parameters, preparation, analysis, pore
pressure prediction, exponent, shale density; Well completion - well completion techniques, perforation and tools for perforation; Applications of formation evaluation.
Text Books
1. Formation evaluation by Edward J. Lynch
2. Fundamentals of well log interpretation – the acquisition of well log data by O. Serra, Elsevier
Science Publishing company, Inc., New York.
Reference books:
1. Log interpretation principles/Applications, Schlumberger educational services, Texas, USA.
403: Petroleum geology and geophysics (Elective Paper)
UNIT I: Physical and Chemical properties of Hydrocarbon and nonhydrocarbon gases, gas hydrates and crude
oil; Composition, occurrence and economic significance of gas hydrates, identification of gas hydrates;
Classification of crude oil, Origin of Petroleum – organic, inorganic, thermogenic, biogenic, source rocks, nature and types, characterization, evaluation of source rock potential; Genesis of petroleum by Fisher-
Tropsch synthesis.
UNIT II: Migration of petroleum, primary and secondary, mechanics of oil and gas movement through pore space; Maturation concepts, qualitative and quantitative evaluation, chemical and optical methods of Kerogen
and bitumen analysis, diagenesis, catagenesis and metagenesis, TTI concept, measurement of the distance or
petroleum migration.
UNIT III: Definitions of porosity, permeability, classification of porosity, measurement of porosity,
permeability, interpretation of permeability data, relationship between porosity, permeability and grain size,
shape, packing, sorting, orientation and depositional process; Reservoir rocks - clastic, carbonate and unconventional reservoir rocks; Reservoir traps - Nomenclature, distribution of petroleum within a trap,
classification of traps – structural, stratigraphic diapiric, hydrodynamic and combinational traps;
UNIT IV: Nonconventional energy resources: Plastic and solid hydrocarbons – occurrence and composition;
Tar sands – Composition, geological distribution and origin of tar sands; Oil shales – Chemical composition,
distribution of oil shales; Coal Bed Methane: Environments of deposition of coal beds, coal grades, concept of
cleats, mineral composition of coal, drilling for coal bed methane, core studies, logging of coal beds and
evaluation, dewatering and CBM production, estimation of gas in place, shale gas.
Application of surface geophysical techniques viz., gravity, magnetic and seismics for hydrocarbon
exploration; Application of various subsurface geophysical and/or well logging techniques for hydrocarbon exploration and basin analysis.
Text Books:
1. Geology of Petroleum by A. I. Leverson,
2. Elements of Petroleum Geology by Richard C. Shelley, 1985, Second edition, Academic Press,
California, USA.
Reference books:
1. Geosciences in petroleum exploration: Fundamentals of geology, geophysics, petrophysics and
drilling engineering techniques applied in petroleum exploration by Kapish Sinha, Amazon Asia-
Pacific Holdings Private limited,
403: Environmental and Groundwater Geophysics (Elective Paper)
UNIT I: Hydrologic Cycle, the groundwater in the hydrologic cycle; Hydrologic budget; Origin and
Occurrence of groundwater – Origin of groundwater, rock properties affecting groundwater, vertical
distribution of groundwater, geologic formations as aquifers, types of aquifers, groundwater basins and regional groundwater flow systems, springs, hydrothermal phenomena, groundwater in permafrost regions.
UNIT II: Groundwater movement – Darcy’s Law, verification and validity; Permeability, intrinsic permeability, hydraulic conductivity, transmissivity, hydraulic conductivity of geologic materials,
determination of hydraulic conductivity; Groundwater flow rates and flow directions, general flow equation,
unsaturated flow, infiltration.
UNIT III: Quality of Groundwater – Salinity in groundwater, sources of salinity, measures of water quality,
groundwater samples, chemical analysis, physical analysis, biological analysis, water quality criteria, changes in chemical composition, dissolved gases, temperature; Pollution in groundwater – Municipal sources,
industrial sources, agricultural sources, miscellaneous sources and their causes; Monitoring of groundwater
quality, remediation of contaminated groundwater; Application of various geophysical techniques in ground
water pollution identification and mapping.
UNIT IV: Saline water intrusion in aquifers – occurrence, structure and shape of fresh-salt water interface,
effect of seawater intrusion, control of saline water intrusion, identification of saline water intrusion with the help of geophysical techniques.
Surface and subsurface investigations of groundwater – Geological, remote sensing and geophysical exploration (electrical, seismic and potential field methods) techniques; Application of various geophysical
logging techniques (resistivity, SP, natural gamma, gamma-gamma, neutron, temperature, caliper, acoustic
etc.) for groundwater investigations.
Text Books/Reference books:
1. Groundwater hydrology by David Keith Todd and Larry W. Mays, 2005, Third edition, John Wiley
and Sons, Inc.
2. Application of surface geophysics for groundwater investigations by A.A. R. Zohdy, G. P. Eaton, and
D. R. Mabey, U.S. Geological survey, 1990.
3. Ground water by H. M. Raghunath, New age international publications.